% $Id: manual.tex,v 1.38 2000/05/12 19:49:18 roberto Exp roberto $ \documentclass[11pt]{article} \usepackage{fullpage,bnf} \usepackage{graphicx} %\usepackage{times} \catcode`\_=12 \newcommand{\See}[1]{Section~\ref{#1}} \newcommand{\see}[1]{(see \See{#1})} \newcommand{\M}[1]{\rm\emph{#1}} \newcommand{\T}[1]{{\tt #1}} \newcommand{\Math}[1]{$#1$} \newcommand{\nil}{{\bf nil}} \def\tecgraf{{\sf TeC\kern-.21em\lower.7ex\hbox{Graf}}} \newcommand{\Index}[1]{#1\index{#1}} \newcommand{\IndexVerb}[1]{\T{#1}\index{#1}} \newcommand{\IndexEmph}[1]{\emph{#1}\index{#1}} \newcommand{\Def}[1]{\emph{#1}\index{#1}} \newcommand{\Deffunc}[1]{\index{#1}} \newcommand{\ff}{$\bullet$\ } \newcommand{\Version}{4.0} % LHF \renewcommand{\ter}[1]{{\rm`{\tt#1}'}} \newcommand{\NOTE}{\par\noindent\emph{NOTE}: } \makeindex \begin{document} %{=============================================================== \thispagestyle{empty} \pagestyle{empty} { \parindent=0pt \vglue1.5in {\LARGE\bf The Programming Language Lua} \hfill \vskip4pt \hrule height 4pt width \hsize \vskip4pt \hfill Reference Manual for Lua version \Version \\ \null \hfill Last revised on \today \\ \vfill \centering \includegraphics[width=0.7\textwidth]{nolabel.ps} \vfill \vskip4pt \hrule height 2pt width \hsize } \newpage \begin{quotation} \parskip=10pt \footnotesize \null\vfill \noindent Copyright \copyright\ 1994--2000 TeCGraf, PUC-Rio. All rights reserved. \noindent Permission is hereby granted, without written agreement and without license or royalty fees, to use, copy, modify, and distribute this software and its documentation for any purpose, including commercial applications, subject to the following conditions: \begin{itemize} \item The above copyright notice and this permission notice shall appear in all copies or substantial portions of this software. \item The origin of this software must not be misrepresented; you must not claim that you wrote the original software. If you use this software in a product, an acknowledgment in the product documentation would be greatly appreciated (but it is not required). \item Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software. \end{itemize} The authors specifically disclaim any warranties, including, but not limited to, the implied warranties of merchantability and fitness for a particular purpose. The software provided hereunder is on an ``as is'' basis, and the authors have no obligation to provide maintenance, support, updates, enhancements, or modifications. In no event shall TeCGraf, PUC-Rio, or the authors be held liable to any party for direct, indirect, special, incidental, or consequential damages arising out of the use of this software and its documentation. \noindent The Lua language and this implementation have been entirely designed and written by Waldemar Celes, Roberto Ierusalimschy and Luiz Henrique de Figueiredo at TeCGraf, PUC-Rio. \noindent This implementation contains no third-party code. \noindent Copies of this manual can be obtained at \verb|http://www.tecgraf.puc-rio.br/lua/|. \end{quotation} %}=============================================================== \newpage \title{Reference Manual of the Programming Language Lua \Version} \author{% Roberto Ierusalimschy\quad Luiz Henrique de Figueiredo\quad Waldemar Celes \vspace{1.0ex}\\ \smallskip \small\tt lua@tecgraf.puc-rio.br \vspace{2.0ex}\\ %MCC 08/95 --- \tecgraf\ --- Computer Science Department --- PUC-Rio } \date{{\small \tt\$Date: 2000/05/12 19:49:18 $ $}} \maketitle \thispagestyle{empty} \pagestyle{empty} \begin{abstract} \noindent Lua is a powerful, light-weight programming language designed for extending applications. Lua is also frequently used as a general-purpose, stand-alone language. Lua combines simple procedural syntax (similar to Pascal) with powerful data description constructs based on associative arrays and extensible semantics. Lua is dynamically typed, interpreted from bytecodes, and has automatic memory management with garbage collection, making it ideal for configuration, scripting, and rapid prototyping. This document describes version \Version\ of the Lua programming language and the API that allows interaction between Lua programs and their host C programs. \end{abstract} \def\abstractname{Resumo} \begin{abstract} \noindent Lua \'e uma linguagem de programa\c{c}\~ao poderosa e leve, projetada para extender aplica\c{c}\~oes. Lua tamb\'em \'e frequentemente usada como uma linguagem de prop\'osito geral. Lua combina programa\c{c}\~ao procedural (com sintaxe semelhante \`a de Pascal) com poderosas constru\c{c}\~oes para descri\c{c}\~ao de dados, baseadas em tabelas associativas e sem\^antica extens\'\i vel. Lua \'e tipada dinamicamente, interpretada a partir de \emph{bytecodes}, e tem gerenciamento autom\'atico de mem\'oria com coleta de lixo. Essas caracter\'{\i}sticas fazem de Lua uma linguagem ideal para configura\c{c}\~ao, automa\c{c}\~ao (\emph{scripting}) e prototipagem r\'apida. Este documento descreve a vers\~ao \Version\ da linguagem de programa\c{c}\~ao Lua e a Interface de Programa\c{c}\~ao (API) que permite a intera\c{c}\~ao entre programas Lua e programas C hospedeiros. \end{abstract} \newpage \null \newpage \tableofcontents \newpage \setcounter{page}{1} \pagestyle{plain} \section{Introduction} Lua is an extension programming language designed to support general procedural programming with data description facilities. Lua is intended to be used as a powerful, light-weight configuration language for any program that needs one. Lua is implemented as a library, written in C. Being an extension language, Lua has no notion of a ``main'' program: it only works \emph{embedded} in a host client, called the \emph{embedding} program. This host program can invoke functions to execute a piece of code in Lua, can write and read Lua variables, and can register C~functions to be called by Lua code. Through the use of C~functions, Lua can be augmented to cope with a wide range of different domains, thus creating customized programming languages sharing a syntactical framework. Lua is free-distribution software, and provided as usual with no guarantees, as stated in the copyright notice. The implementation described in this manual is available at the following URL's: \begin{verbatim} http://www.tecgraf.puc-rio.br/lua/ ftp://ftp.tecgraf.puc-rio.br/pub/lua/ \end{verbatim} Like any other reference manual, this document is dry in places. For a discussion of the decisions behind the design of Lua, see the papers below, which are available at the web site above. \begin{itemize} \item R.~Ierusalimschy, L.~H.~de Figueiredo, and W.~Celes. Lua---an extensible extension language. \emph{Software: Practice \& Experience} {\bf 26} \#6 (1996) 635--652. \item L.~H.~de Figueiredo, R.~Ierusalimschy, and W.~Celes. The design and implementation of a language for extending applications. \emph{Proceedings of XXI Brazilian Seminar on Software and Hardware} (1994) 273--283. \item L.~H.~de Figueiredo, R.~Ierusalimschy, and W.~Celes. Lua: an extensible embedded language. \emph{Dr. Dobb's Journal} {\bf 21} \#12 (Dec 1996) 26--33. \end{itemize} \section{Environment and Chunks} All statements in Lua are executed in a \Def{global environment}. This environment, which keeps all global variables, is initialized with a call from the embedding program to \verb|lua_newstate| and persists until a call to \verb|lua_close|, or the end of the embedding program. Optionally, a user can create multiple independent global environments, and freely switch between them \see{mangstate}. The global environment can be manipulated by Lua code or by the embedding program, which can read and write global variables using API functions from the library that implements Lua. \Index{Global variables} do not need declaration. Any variable is assumed to be global unless explicitly declared local \see{localvar}. Before the first assignment, the value of a global variable is \nil; this default can be changed \see{tag-method}. The unit of execution of Lua is called a \Def{chunk}. A chunk is simply a sequence of statements: \begin{Produc} \produc{chunk}{\rep{stat} \opt{ret}} \end{Produc}% Statements are described in \See{stats}. (The notation above is the usual extended BNF, in which \rep{\emph{a}} means 0 or more \emph{a}'s, \opt{\emph{a}} means an optional \emph{a}, and \oneormore{\emph{a}} means one or more \emph{a}'s.) A chunk may be in a file or in a string inside the host program. A chunk may optionally end with a \verb|return| statement \see{return}. When a chunk is executed, first all its code is pre-compiled, and then the statements are executed in sequential order. All modifications a chunk effects on the global environment persist after the chunk ends. Chunks may also be pre-compiled into binary form; see program \IndexVerb{luac} for details. Text files with chunks and their binary pre-compiled forms are interchangeable. Lua automatically detects the file type and acts accordingly. \index{pre-compilation} \section{\Index{Types and Tags}} \label{TypesSec} Lua is a \emph{dynamically typed language}. This means that variables do not have types; only values do. Therefore, there are no type definitions in the language. All values carry their own type. Besides a type, all values also have a \IndexEmph{tag}. There are six \Index{basic types} in Lua: \Def{nil}, \Def{number}, \Def{string}, \Def{function}, \Def{userdata}, and \Def{table}. \emph{Nil} is the type of the value \nil, whose main property is to be different from any other value. \emph{Number} represents real (double-precision floating-point) numbers, while \emph{string} has the usual meaning. Lua is \Index{eight-bit clean}, and so strings may contain any 8-bit character, \emph{including} embedded zeros (\verb|'\0'|) \see{lexical}. The \verb|type| function returns a string describing the type of a given value \see{pdf-type}. Functions are considered \emph{first-class values} in Lua. This means that functions can be stored in variables, passed as arguments to other functions, and returned as results. Lua can call (and manipulate) functions written in Lua and functions written in C. The kinds of functions can be distinguished by their tags: all Lua functions have the same tag, and all C~functions have the same tag, which is different from the tag of Lua functions. The \verb|tag| function returns the tag of a given value \see{pdf-tag}. The type \emph{userdata} is provided to allow arbitrary \Index{C pointers} to be stored in Lua variables. It corresponds to a \verb|void*| and has no pre-defined operations in Lua, besides assignment and equality test. However, by using \emph{tag methods}, the programmer can define operations for \emph{userdata} values \see{tag-method}. The type \emph{table} implements \Index{associative arrays}, that is, \Index{arrays} that can be indexed not only with numbers, but with any value (except \nil). Therefore, this type may be used not only to represent ordinary arrays, but also symbol tables, sets, records, etc. Tables are the main data structuring mechanism in Lua. To represent \Index{records}, Lua uses the field name as an index. The language supports this representation by providing \verb|a.name| as syntactic sugar for \verb|a["name"]|. Tables may also carry \emph{methods}: Because functions are first class values, table fields may contain functions. The form \verb|t:f(x)| is syntactic sugar for \verb|t.f(t,x)|, which calls the method \verb|f| from the table \verb|t| passing itself as the first parameter \see{func-def}. Note that tables are \emph{objects}, and not values. Variables cannot contain tables, only \emph{references} to them. Assignment, parameter passing, and returns always manipulate references to tables, and do not imply any kind of copy. Moreover, tables must be explicitly created before used \see{tableconstructor}. Tags are mainly used to select \emph{tag methods} when some events occur. Tag methods are the main mechanism for extending the semantics of Lua \see{tag-method}. Each of the types \M{nil}, \M{number}, and \M{string} has a different tag. All values of each of these types have the same pre-defined tag. Values of type \M{function} can have two different tags, depending on whether they are Lua functions or C~functions. Finally, values of type \M{userdata} and \M{table} have variable tags, assigned by the program \see{tag-method}. Tags are created with the function \verb|newtag|, and the function \verb|tag| returns the tag of a given value. To change the tag of a given table, there is the function \verb|settag| \see{pdf-newtag}. \section{The Language} This section describes the lexis, the syntax, and the semantics of Lua. \subsection{Lexical Conventions} \label{lexical} \IndexEmph{Identifiers} in Lua can be any string of letters, digits, and underscores, not beginning with a digit. This coincides with the definition of identifiers in most languages, except that the definition of letter depends on the current locale: Any character considered alphabetic by the current locale can be used in an identifier. The following words are \emph{reserved}, and cannot be used as identifiers: \index{reserved words} \begin{verbatim} and break do else elseif end for function if local nil not or repeat return then until while \end{verbatim} Lua is a case-sensitive language: \T{and} is a reserved word, but \T{And} and \T{\'and} (if the locale permits) are two different, valid identifiers. As a convention, identifiers starting with underscore followed by uppercase letters (such as \verb|_INPUT|) are reserved for internal variables. The following strings denote other \Index{tokens}: \begin{verbatim} ~= <= >= < > == = + - * / % ( ) { } [ ] ; , . .. ... \end{verbatim} \IndexEmph{Literal strings} can be delimited by matching single or double quotes, and can contain the C-like escape sequences \verb|'\a'| (bell), \verb|'\b'| (backspace), \verb|'\f'| (form feed), \verb|'\n'| (newline), \verb|'\r'| (carriage return), \verb|'\t'| (horizontal tab), \verb|'\v'| (vertical tab), \verb|'\\'|, (backslash), \verb|'\"'|, (double quote), \verb|'\''| (single quote), and \verb|'\|\emph{newline}\verb|'| (that is, a backslash followed by a real newline, which results in a newline in the string). A character in a string may also be specified by its numerical value, through the escape sequence \verb|'\ddd'|, where \verb|ddd| is a sequence of up to three \emph{decimal} digits. Strings in Lua may contain any 8-bit value, including embedded zeros, which can be specified as \verb|'\000'|. Literal strings can also be delimited by matching \verb|[[| \dots\ \verb|]]|. Literals in this bracketed form may run for several lines, may contain nested \verb|[[ ... ]]| pairs, and do not interpret escape sequences. This form is specially convenient for writing strings that contain program pieces or other quoted strings. As an example, in a system using ASCII, the following three literals are equivalent: \begin{verbatim} 1) "alo\n123\"" 2) '\97lo\10\04923"' 3) [[alo 123"]] \end{verbatim} \Index{Comments} start anywhere outside a string with a double hyphen (\verb|--|) and run until the end of the line. Moreover, the first line of a chunk is skipped if it starts with \verb|#|. This facility allows the use of Lua as a script interpreter in Unix systems \see{lua-sa}. \Index{Numerical constants} may be written with an optional decimal part, and an optional decimal exponent. Examples of valid numerical constants are \begin{verbatim} 3 3.0 3.1416 314.16e-2 0.31416E1 \end{verbatim} \subsection{The \Index{Pre-processor}} \label{pre-processor} All lines that start with a \verb|$| sign are handled by a pre-processor. The following directives are understood by the pre-processor: \begin{description} \item[\T{\$debug}] --- turn on debugging facilities \see{pragma}. \item[\T{\$nodebug}] --- turn off debugging facilities \see{pragma}. \item[\T{\$if \M{cond}}] --- start a conditional part. If \M{cond} is false, then this part is skipped by the lexical analyzer. \item[\T{\$ifnot \M{cond}}] --- start a conditional part. If \M{cond} is true, then this part is skipped by the lexical analyzer. \item[\T{\$end}] --- end a conditional part. \item[\T{\$else}] --- start an ``else'' conditional part, flipping the ``skip'' status. \item[\T{\$endinput}] --- end the lexical parse of the chunk. For all purposes, it is as if the chunk physically ended at this point. \end{description} Directives may be freely nested. In particular, a \verb|$endinput| may occur inside a \verb|$if|; in that case, even the matching \verb|$end| is not parsed. A \M{cond} part may be \begin{description} \item[\T{nil}] --- always false. \item[\T{1}] --- always true. \item[\T{\M{name}}] --- true if the value of the global variable \M{name} is different from \nil. Note that \M{name} is evaluated \emph{before} the chunk starts its execution. Therefore, actions in a chunk do not affect its own conditional directives. \end{description} \subsection{\Index{Coercion}} \label{coercion} Lua provides some automatic conversions between values at run time. Any arithmetic operation applied to a string tries to convert that string to a number, following the usual rules. Conversely, whenever a number is used when a string is expected, that number is converted to a string, in a reasonable format. The format is chosen so that a conversion from number to string then back to number reproduces the original number \emph{exactly}. Thus, the conversion does not necessarily produces nice-looking text for some numbers. For complete control on how numbers are converted to strings, use the \verb|format| function \see{format}. \subsection{\Index{Adjustment}} \label{adjust} Functions in Lua can return many values. Because there are no type declarations, when a function is called the system does not know how many values the function will return, or how many parameters it needs. Therefore, sometimes, a list of values must be \emph{adjusted}, at run time, to a given length. If there are more values than are needed, then the excess values are thrown away. If there are less values than are needed, then the list is extended with as many \nil's as needed. This adjustment occurs in multiple assignments \see{assignment} and function calls \see{functioncall}. \subsection{Statements}\label{stats} Lua supports an almost conventional set of \Index{statements}, similar to those in Pascal or C. The conventional commands include assignment, control structures, and procedure calls. Non-conventional commands include table constructors \see{tableconstructor} and local variable declarations \see{localvar}. \subsubsection{Blocks} A \Index{block} is a list of statements, which are executed sequentially. A statement may be have an optional \Index{label}, which is syntactically an identifier, and can be optionally followed by a semicolon: \begin{Produc} \produc{block}{\opt{label} \rep{stat \opt{\ter{;}}}} \produc{label}{\ter{$\vert$} name \ter{$\vert$}} \end{Produc}% \NOTE For syntactic reasons, the \rwd{return} and \rwd{break} statements can only be written as the last statement of a block. A block may be explicitly delimited: \begin{Produc} \produc{stat}{\rwd{do} block \rwd{end}} \end{Produc}% This is useful to control the scope of local variables \see{localvar}, and to add a \rwd{return} or \rwd{break} statement in the middle of another block: \begin{verbatim} do return end -- return is the last statement in this block \end{verbatim} \subsubsection{\Index{Assignment}} \label{assignment} The language allows \Index{multiple assignment}. Therefore, the syntax for assignment defines a list of variables on the left side and a list of expressions on the right side. Both lists have their elements separated by commas: \begin{Produc} \produc{stat}{varlist1 \ter{=} explist1} \produc{varlist1}{var \rep{\ter{,} var}} \end{Produc}% This statement first evaluates all values on the right side and eventual indices on the left side, and then makes the assignments. So \begin{verbatim} i = 3 i, a[i] = 4, 20 \end{verbatim} sets \verb|a[3]| to 20, but does not affect \verb|a[4]|. Multiple assignment can be used to exchange two values, as in \begin{verbatim} x, y = y, x \end{verbatim} The two lists in a multiple assignment may have different lengths. Before the assignment, the list of values is adjusted to the length of the list of variables \see{adjust}. A single name can denote a global variable, a local variable, or a formal parameter: \begin{Produc} \produc{var}{name} \end{Produc}% Square brackets are used to index a table: \begin{Produc} \produc{var}{simpleexp \ter{[} exp1 \ter{]}} \end{Produc}% The \M{simpleexp} should result in a table value, from where the field indexed by the expression \M{exp1} value gets the assigned value. The syntax \verb|var.NAME| is just syntactic sugar for \verb|var["NAME"]|: \begin{Produc} \produc{var}{simpleexp \ter{.} name} \end{Produc}% The meaning of assignments and evaluations of global variables and indexed variables can be changed by tag methods \see{tag-method}. Actually, an assignment \verb|x = val|, where \verb|x| is a global variable, is equivalent to a call \verb|setglobal("x", val)|; an assignment \verb|t[i] = val| is equivalent to \verb|settable_event(t,i,val)|. See \See{tag-method} for a complete description of these functions. (The function \verb|setglobal| is pre-defined in Lua. The function \T{settable\_event} is used only for explanatory purposes.) \subsubsection{Control Structures} The control structures \index{while-do}\index{repeat-until}\index{if-then-else}% \T{if}, \T{while}, and \T{repeat} have the usual meaning and familiar syntax: \begin{Produc} \produc{stat}{\rwd{while} exp1 \rwd{do} block \rwd{end}} \produc{stat}{\rwd{repeat} block \rwd{until} exp1} \produc{stat}{\rwd{if} exp1 \rwd{then} block \rep{\rwd{elseif} exp1 \rwd{then} block} \opt{\rwd{else} block} \rwd{end}} \end{Produc}% The \Index{condition expression} \M{exp1} of a control structure may return any value. All values different from \nil\ are considered true; only \nil\ is considered false. \index{return} The \rwd{return} statement is used to return values from a function or from a chunk. \label{return} Because functions or chunks may return more than one value, the syntax for a \Index{return statement} is \begin{Produc} \produc{stat}{\rwd{return} \opt{explist1}} \end{Produc}% \index{break} The \rwd{break} statement can be used to terminate the execution of a block, skipping to the next statement after the block: \begin{Produc} \produc{stat}{\rwd{break} \opt{name}} \end{Produc}% A \rwd{break} without a label ends the innermost enclosing loop (while, repeat, or for). A \rwd{break} with a label breaks the innermost enclosing statement with that label. Thus, labels do not have to be unique. For syntactic reasons, \rwd{return} and \rwd{break} statements can only be written as the last statement of a block. \subsubsection{For Statement} \label{for}\index{for} The \rwd{for} statement has the following syntax: \begin{Produc} \produc{stat}{\rwd{for} name \ter{=} exp1 \ter{,} exp1 \opt{\ter{,} exp1} \rwd{do} block \rwd{end}} \end{Produc}% A \rwd{for} statement like \begin{verbatim} for var=e1,e2,e3 do block end \end{verbatim} is equivalent to the following code: \begin{verbatim} do local var, _limit, _step = tonumber(e1), tonumber(e2), tonumber(e3) if not (var and _limit and _step) then error() end while (_step>0 and var<=_limit) or (_step<=0 and var>=_limit) do block var = var+_step end end \end{verbatim} Notice the following: \begin{itemize}\itemsep=0pt \item \verb|_limit| and \verb|_step| are invisible variables. The names are here for explanatory purposes only. \item The behavior is \emph{undefined} if you assign to \verb|var| inside the block. \item If the third expression (the step) is absent, then a step of 1 is used. \item Both the limit and the step are evaluated only once, before the loop starts. \item The variable \verb|var| is local to the statement; you cannot use its value after the \rwd{for} ends. \item You can use \rwd{break} to exit a \rwd{for}. If you need the value of the index, then assign it to another variable before breaking. \end{itemize} \subsubsection{Function Calls as Statements} \label{funcstat} Because of possible side-effects, function calls can be executed as statements: \begin{Produc} \produc{stat}{functioncall} \end{Produc}% In this case, all returned values are thrown away. Function calls are explained in \See{functioncall}. \subsubsection{Local Declarations} \label{localvar} \Index{Local variables} may be declared anywhere inside a block. The declaration may include an initial assignment: \begin{Produc} \produc{stat}{\rwd{local} declist \opt{init}} \produc{declist}{name \rep{\ter{,} name}} \produc{init}{\ter{=} explist1} \end{Produc}% If present, an initial assignment has the same semantics of a multiple assignment. Otherwise, all variables are initialized with \nil. The scope of local variables begins \emph{after} the declaration and lasts until the end of the block. Thus, the code \verb|local print=print| creates a local variable called \verb|print| whose initial value is that of the \emph{global} variable of the same name. \subsection{\Index{Expressions}} \subsubsection{\Index{Basic Expressions}} The basic expressions in Lua are \begin{Produc} \produc{exp}{\ter{(} exp \ter{)}} \produc{exp}{\rwd{nil}} \produc{exp}{number} \produc{exp}{literal} \produc{exp}{function} \produc{exp}{simpleexp} \end{Produc}% \begin{Produc} \produc{simpleexp}{var} \produc{simpleexp}{upvalue} \produc{simpleexp}{functioncall} \produc{simpleexp}{tableconstructor} \end{Produc}% Numbers (numerical constants) and literal strings are explained in \See{lexical}; variables are explained in \See{assignment}; upvalues are explained in \See{upvalue}; function definitions (\M{function}) are explained in \See{func-def}; function calls are explained in \See{functioncall}. Table constructors are explained in \See{tableconstructor}. An access to a global variable \verb|x| is equivalent to a call \verb|getglobal("x")|; an access to an indexed variable \verb|t[i]| is equivalent to a call \verb|gettable_event(t,i)|. See \See{tag-method} for a description of these functions. (Function \verb|getglobal| is pre-defined in Lua. Function \T{gettable\_event} is used only for explanatory purposes.) The non-terminal \M{exp1} is used to indicate that the values returned by an expression must be adjusted to one single value: \begin{Produc} \produc{exp1}{exp} \end{Produc}% \subsubsection{Arithmetic Operators} Lua supports the usual \Index{arithmetic operators}: the binary \verb|+| (addition), \verb|-| (subtraction), \verb|*| (multiplication), \verb|/| (division) and \verb|^| (exponentiation), and unary \verb|-| (negation). If the operands are numbers, or strings that can be converted to numbers (according to the rules given in \See{coercion}), then all operations except exponentiation have the usual meaning. Otherwise, an appropriate tag method is called \see{tag-method}. An exponentiation always calls a tag method. The standard mathematical library redefines this method for numbers, giving the expected meaning to \Index{exponentiation} \see{mathlib}. \subsubsection{Relational Operators} Lua provides the following \Index{relational operators}: \begin{verbatim} == ~= < > <= >= \end{verbatim} All these return \nil\ as false and a value different from \nil\ as true. Equality first compares the tags of its operands. If they are different, then the result is \nil. Otherwise, their values are compared. Numbers and strings are compared in the usual way. Tables, userdata, and functions are compared by reference, that is, two tables are considered equal only if they are the \emph{same} table. The operator \verb|~=| is exactly the negation of equality (\verb|==|). \NOTE The conversion rules of \See{coercion} \emph{do not} apply to equality comparisons. Thus, \verb|"0"==0| evaluates to \emph{false}, and \verb|t[0]| and \verb|t["0"]| denote different entries in a table. The order operators work as follows. If both arguments are numbers, then they are compared as such. Otherwise, if both arguments are strings, then their values are compared using lexicographical order. Otherwise, the ``lt'' tag method is called \see{tag-method}. \subsubsection{Logical Operators} The \Index{logical operators} are \index{and}\index{or}\index{not} \begin{verbatim} and or not \end{verbatim} Like control structures, all logical operators consider \nil\ as false and anything else as true. The conjunction operator \verb|and| returns \nil\ if its first argument is \nil; otherwise, it returns its second argument. The disjunction operator \verb|or| returns its first argument if it is different from \nil; otherwise, it returns its second argument. Both \verb|and| and \verb|or| use \Index{short-cut evaluation}, that is, the second operand is evaluated only when necessary. There are two useful Lua idioms with logical operators. The first idiom is \verb|x = x or v|, which is equivalent to \begin{verbatim} if x == nil then x = v end \end{verbatim} i.e., it sets \verb|x| to a default value \verb|v| when \verb|x| is not set. The other idiom is \verb|x = a and b or c|, which should be read as \verb|x = a and (b or c)|, is equivalent to \begin{verbatim} if a then x = b else x = c end \end{verbatim} provided that \verb|b| is not \nil. \subsubsection{Concatenation} The string \Index{concatenation} operator in Lua is denoted by ``\IndexVerb{..}''. If both operands are strings or numbers, they are converted to strings according to the rules in \See{coercion}. Otherwise, the ``concat'' tag method is called \see{tag-method}. \subsubsection{Precedence} \Index{Operator precedence} follows the table below, from the lower to the higher priority: \begin{verbatim} and or < > <= >= ~= == .. + - * / not - (unary) ^ \end{verbatim} All binary operators are left associative, except for \verb|^| (exponentiation), which is right associative. \NOTE The pre-compiler may rearrange the order of evaluation of associative operators (such as~\verb|..| or~\verb|+|), as long as these optimizations do not change normal results. However, these optimizations may change some results if you define non-associative tag methods for these operators. \subsubsection{Table Constructors} \label{tableconstructor} Table \Index{constructors} are expressions that create tables; every time a constructor is evaluated, a new table is created. Constructors can be used to create empty tables, or to create a table and initialize some fields. The general syntax for constructors is \begin{Produc} \produc{tableconstructor}{\ter{\{} fieldlist \ter{\}}} \produc{fieldlist}{lfieldlist \Or ffieldlist \Or lfieldlist \ter{;} ffieldlist \Or ffieldlist \ter{;} lfieldlist} \produc{lfieldlist}{\opt{lfieldlist1}} \produc{ffieldlist}{\opt{ffieldlist1}} \end{Produc}% The form \emph{lfieldlist1} is used to initialize lists: \begin{Produc} \produc{lfieldlist1}{exp \rep{\ter{,} exp} \opt{\ter{,}}} \end{Produc}% The expressions in the list are assigned to consecutive numerical indices, starting with 1. For example, \begin{verbatim} a = {"v1", "v2", 34} \end{verbatim} is equivalent to \begin{verbatim} do local temp = {} temp[1] = "v1" temp[2] = "v2" temp[3] = 34 a = temp end \end{verbatim} The form \emph{ffieldlist1} initializes other fields in a table: \begin{Produc} \produc{ffieldlist1}{ffield \rep{\ter{,} ffield} \opt{\ter{,}}} \produc{ffield}{\ter{[} exp \ter{]} \ter{=} exp \Or name \ter{=} exp} \end{Produc}% For example, \begin{verbatim} a = {[f(k)] = g(y), x = 1, y = 3, [0] = b+c} \end{verbatim} is equivalent to \begin{verbatim} do local temp = {} temp[f(k)] = g(y) temp.x = 1 -- or temp["x"] = 1 temp.y = 3 -- or temp["y"] = 3 temp[0] = b+c a = temp end \end{verbatim} An expression like \verb|{x = 1, y = 4}| is in fact syntactic sugar for \verb|{["x"] = 1, ["y"] = 4}|. Both forms may have an optional trailing comma, and can be used in the same constructor separated by a semi-collon. For example, all forms below are correct. \begin{verbatim} x = {;} x = {"a", "b",} x = {type="list"; "a", "b"} x = {f(0), f(1), f(2),; n=3,} \end{verbatim} \subsubsection{Function Calls} \label{functioncall} A \Index{function call} has the following syntax: \begin{Produc} \produc{functioncall}{simpleexp args} \end{Produc}% First, \M{simpleexp} is evaluated. If its value has type \emph{function}, then this function is called, with the given arguments. Otherwise, the ``function'' tag method is called, having as first parameter the value of \M{simpleexp}, and then the original call arguments. The form \begin{Produc} \produc{functioncall}{simpleexp \ter{:} name args} \end{Produc}% can be used to call ``methods''. A call \verb|simpleexp:name(...)| is syntactic sugar for \begin{verbatim} simpleexp.name(simpleexp, ...) \end{verbatim} except that \verb|simpleexp| is evaluated only once. Arguments have the following syntax: \begin{Produc} \produc{args}{\ter{(} \opt{explist1} \ter{)}} \produc{args}{tableconstructor} \produc{args}{\ter{literal}} \produc{explist1}{\rep{exp1 \ter{,}} exp} \end{Produc}% All argument expressions are evaluated before the call. A call of the form \verb|f{...}| is syntactic sugar for \verb|f({...})|, that is, the parameter list is a single new table. A call of the form \verb|f'...'| (or \verb|f"..."| or \verb|f[[...]]|) is syntactic sugar for \verb|f('...')|, that is, the parameter list is a single literal string. Because a function can return any number of results \see{return}, the number of results must be adjusted before used. If the function is called as a statement \see{funcstat}, then its return list is adjusted to~0, thus discarding all returned values. If the function is called in a place that needs a single value (syntactically denoted by the non-terminal \M{exp1}), then its return list is adjusted to~1, thus discarding all returned values but the first one. If the function is called in a place that can hold many values (syntactically denoted by the non-terminal \M{exp}), then no adjustment is made. The only places that can hold many values is the last (or the only) expression in an assignment, in an argument list, or in a return statement. Here are some examples. \begin{verbatim} f(); -- adjusted to 0 g(f(), x); -- f() is adjusted to 1 result g(x, f()); -- g gets x plus all values returned by f() a,b,c = f(), x; -- f() is adjusted to 1 result (and c gets nil) a,b,c = x, f(); -- f() is adjusted to 2 a,b,c = f(); -- f() is adjusted to 3 return f(); -- returns all values returned by f() return x,y,f(); -- returns a, b, and all values returned by f() \end{verbatim} \subsubsection{\Index{Function Definitions}} \label{func-def} The syntax for function definition is \begin{Produc} \produc{function}{\rwd{function} \ter{(} \opt{parlist1} \ter{)} block \rwd{end}} \produc{stat}{\rwd{function} funcname \ter{(} \opt{parlist1} \ter{)} block \rwd{end}} \produc{funcname}{name \Or name \ter{.} name \Or name \ter{:} name} \end{Produc}% The statement \begin{verbatim} function f () ... end \end{verbatim} is just syntactic sugar for \begin{verbatim} f = function () ... end \end{verbatim} and the statement \begin{verbatim} function o.f () ... end \end{verbatim} is syntactic sugar for \begin{verbatim} o.f = function () ... end \end{verbatim} A function definition is an executable expression, whose value has type \emph{function}. When Lua pre-compiles a chunk, all its function bodies are pre-compiled, too. Then, whenever Lua executes the function definition, its upvalues are fixed \see{upvalue}, and the function is \emph{instantiated} (or \emph{closed}). This function instance (or \emph{closure}) is the final value of the expression. Different instances of the same function may have different upvalues. Parameters act as local variables, initialized with the argument values: \begin{Produc} \produc{parlist1}{\ter{\ldots}} \produc{parlist1}{name \rep{\ter{,} name} \opt{\ter{,} \ter{\ldots}}} \end{Produc}% \label{vararg} When a function is called, the list of \Index{arguments} is adjusted to the length of the list of parameters \see{adjust}, unless the function is a \Def{vararg} function, which is indicated by the dots (\ldots) at the end of its parameter list. A vararg function does not adjust its argument list; instead, it collects all extra arguments into an implicit parameter, called \IndexVerb{arg}. The value of \verb|arg| is a table, with a field~\verb|n| whose value is the number of extra arguments, and the extra arguments at positions 1,~2,~\ldots,\M{n}. As an example, consider the following definitions: \begin{verbatim} function f(a, b) end function g(a, b, ...) end function r() return 1,2,3 end \end{verbatim} Then, we have the following mapping from arguments to parameters: \begin{verbatim} CALL PARAMETERS f(3) a=3, b=nil f(3, 4) a=3, b=4 f(3, 4, 5) a=3, b=4 f(r(), 10) a=1, b=10 f(r()) a=1, b=2 g(3) a=3, b=nil, arg={n=0} g(3, 4) a=3, b=4, arg={n=0} g(3, 4, 5, 8) a=3, b=4, arg={5, 8; n=2} g(5, r()) a=5, b=1, arg={2, 3; n=2} \end{verbatim} Results are returned using the \verb|return| statement \see{return}. If control reaches the end of a function without encountering a \rwd{return} statement, then the function returns with no results. The syntax \begin{Produc} \produc{funcname}{name \ter{:} name} \end{Produc}% is used for defining \Index{methods}, that is, functions that have an implicit extra parameter \IndexVerb{self}: Thus, the statement \begin{verbatim} function v:f (...) ... end \end{verbatim} is equivalent to \begin{verbatim} v.f = function (self, ...) ... end \end{verbatim} that is, the function gets an extra formal parameter called \verb|self|. Note that the variable \verb|v| must have been previously initialized with a table value. \subsection{Visibility and Upvalues} \label{upvalue} \index{Visibility} \index{Upvalues} A function body may refer to its own local variables (which include its parameters) and to global variables, as long as they are not \emph{shadowed} by local variables from enclosing functions. A function \emph{cannot} access a local variable from an enclosing function, since such variables may no longer exist when the function is called. However, a function may access the \emph{value} of a local variable from an enclosing function, using \emph{upvalues}, whose syntax is \begin{Produc} \produc{upvalue}{\ter{\%} name} \end{Produc}% An upvalue is somewhat similar to a variable expression, but whose value is \emph{frozen} when the function wherein it appears is instantiated. The name used in an upvalue may be the name of any variable visible at the point where the function is defined, that is global variables and local variables from the immediately enclosing function. Here are some examples: \begin{verbatim} a,b,c = 1,2,3 -- global variables local d function f (x) local b -- x and b are local to f; b shadows the global b local g = function (a) local y -- a and y are local to g p = a -- OK, access local 'a' p = c -- OK, access global 'c' p = b -- ERROR: cannot access a variable in outer scope p = %b -- OK, access frozen value of 'b' (local to 'f') p = %c -- OK, access frozen value of global 'c' p = %y -- ERROR: 'y' is not visible where 'g' is defined p = %d -- ERROR: 'd' is not visible where 'g' is defined end -- g end -- f \end{verbatim} \subsection{Error Handling} \label{error} Because Lua is an extension language, all Lua actions start from C~code in the host program calling a function from the Lua library. Whenever an error occurs during Lua compilation or execution, the function \verb|_ERRORMESSAGE| is called \Deffunc{_ERRORMESSAGE} (provided it is different from \nil), and then the corresponding function from the library (\verb|lua_dofile|, \verb|lua_dostring|, \verb|lua_dobuffer|, or \verb|lua_callfunction|) is terminated, returning an error condition. The only argument to \verb|_ERRORMESSAGE| is a string describing the error. The default definition for this function calls \verb|_ALERT|, \Deffunc{_ALERT} which prints the message to \verb|stderr| \see{alert}. The standard I/O library redefines \verb|_ERRORMESSAGE|, and uses the debug facilities \see{debugI} to print some extra information, such as a call stack traceback. To provide more information about errors, Lua programs should include the compilation pragma \verb|$debug|, \index{debug pragma}\label{pragma} or be loaded from the host after calling \verb|lua_setdebug(1)| \see{debugI}. When an error occurs in a chunk compiled with this option, the I/O error-message routine is able to print the number of the lines where the calls (and the error) were made. Lua code can explicitly generate an error by calling the built-in function \verb|error| \see{pdf-error}. Lua code can ``catch'' an error using the built-in function \verb|call| \see{pdf-call}. \subsection{Tag Methods} \label{tag-method} Lua provides a powerful mechanism to extend its semantics, called \Def{tag methods}. A tag method is a programmer-defined function that is called at specific key points during the evaluation of a program, allowing the programmer to change the standard Lua behavior at these points. Each of these points is called an \Def{event}. The tag method called for any specific event is selected according to the tag of the values involved in the event \see{TypesSec}. The function \IndexVerb{settagmethod} changes the tag method associated with a given pair \M{(tag, event)}. Its first parameter is the tag, the second parameter is the event name (a string; see below), and the third parameter is the new method (a function), or \nil\ to restore the default behavior for the pair. The \verb|settagmethod| function returns the previous tag method for that pair. Another function, \IndexVerb{gettagmethod}, receives a tag and an event name and returns the current method associated with the pair. Tag methods are called in the following events, identified by the given names. The semantics of tag methods is better explained by a Lua function describing the behavior of the interpreter at each event. This function not only shows when a tag method is called, but also its arguments, its results, and the default behavior. The code shown here is only \emph{illustrative}; the real behavior is hard coded in the interpreter, and it is much more efficient than this simulation. All functions used in these descriptions (\verb|rawgetglobal|, \verb|tonumber|, \verb|call|, etc.) are described in \See{predefined}. \begin{description} \item[``add'':]\index{add event} called when a \verb|+| operation is applied to non numerical operands. The function \verb|getbinmethod| defines how Lua chooses a tag method for a binary operation. First, Lua tries the first operand. If its tag does not define a tag method for the operation, then Lua tries the second operand. If it also fails, then it gets a tag method from tag~0: \begin{verbatim} function getbinmethod (op1, op2, event) return gettagmethod(tag(op1), event) or gettagmethod(tag(op2), event) or gettagmethod(0, event) end \end{verbatim} Using this function, the tag method for the ``add' event is \begin{verbatim} function add_event (op1, op2) local o1, o2 = tonumber(op1), tonumber(op2) if o1 and o2 then -- both operands are numeric return o1+o2 -- '+' here is the primitive 'add' else -- at least one of the operands is not numeric local tm = getbinmethod(op1, op2, "add") if tm then -- call the method with both operands and an extra -- argument with the event name return tm(op1, op2, "add") else -- no tag method available: default behavior error("unexpected type at arithmetic operation") end end end \end{verbatim} \item[``sub'':]\index{sub event} called when a \verb|-| operation is applied to non numerical operands. Behavior similar to the ``add'' event. \item[``mul'':]\index{mul event} called when a \verb|*| operation is applied to non numerical operands. Behavior similar to the ``add'' event. \item[``div'':]\index{div event} called when a \verb|/| operation is applied to non numerical operands. Behavior similar to the ``add'' event. \item[``pow'':]\index{pow event} called when a \verb|^| operation (exponentiation) is applied. \begin{verbatim} function pow_event (op1, op2) local tm = getbinmethod(op1, op2, "pow") if tm then -- call the method with both operands and an extra -- argument with the event name return tm(op1, op2, "pow") else -- no tag method available: default behavior error("unexpected type at arithmetic operation") end end \end{verbatim} \item[``unm'':]\index{unm event} called when a unary \verb|-| operation is applied to a non numerical operand. \begin{verbatim} function unm_event (op) local o = tonumber(op) if o then -- operand is numeric return -o -- '-' here is the primitive 'unm' else -- the operand is not numeric. -- Try to get a tag method from the operand; -- if it does not have one, try a "global" one (tag 0) local tm = gettagmethod(tag(op), "unm") or gettagmethod(0, "unm") if tm then -- call the method with the operand, nil, and an extra -- argument with the event name return tm(op, nil, "unm") else -- no tag method available: default behavior error("unexpected type at arithmetic operation") end end end \end{verbatim} \item[``lt'':]\index{lt event} called when an order operation is applied to non-numerical or non-string operands. It corresponds to the \verb|<| operator. \begin{verbatim} function lt_event (op1, op2) if type(op1) == "number" and type(op2) == "number" then return op1 < op2 -- numeric comparison elseif type(op1) == "string" and type(op2) == "string" then return op1 < op2 -- lexicographic comparison else local tm = getbinmethod(op1, op2, "lt") if tm then return tm(op1, op2, "lt") else error("unexpected type at comparison"); end end end \end{verbatim} The other order operators use this tag method according to the usual equivalences: \begin{verbatim} a>b <=> b not (b=b <=> not (a